Photocurable liquid polyene-polythiol polymer composition

ABSTRACT

THE INVENTION DISCLOSED IS FOR A NEW PHOTOCURABLE LIQUID POLYMER COMPOSITION WHICH INCLUDES A LIQUID POLYENE COMPONENT HAVING A MOLECULE CONTAINING AT LEAST TWO UNSATURATED CARBON-TO-CARBON BONDS DISPOSED AT TERMINAL POSITIONS ON A MAIN CHAIN OF THE MOLECULE, A POLYTHIOL COMPONENT HAVING A MOLECULE CONTAINING A MULTIPLICITY OF PENDANT OR TERMINALLY POSITIONED -SH FUNCTIONAL GROUPS PER AVERAGE MOLECULE, AND A PHOTCURING RATE ACCELERATOR. THE PHOTOCURABLE LIQUID POLYMER COMPOSITION UPON CURING IN THE PRESENCE OF ACTINIC LIGHT FORMS ORDOLESS, SOLID, ELASTOMERIC OR RESINOUS PRODUCTS WHICH MAY SERVE AS SEALANTS, COATINGS, ADHESIVES AND MOLDED ARTICLES.

United States Patent Oflice 3,697,395 Patented Oct. 10, 1972 3,697,395 PHOTOCURABLE LIQUID POLYENE-POLYTHIOL POLYMER COMPOSITION Clifton L. Kehr, Silver Spring, and Walter R. Wszolek, Sykesville, Md., assignors to W. R. Grace & Co., New York, N.Y.

No Drawing. Division of application Ser. No. 44,607, June 8, 1970, now Patent No. 3,661,744, which is a continuation-in-part of application Ser. No. 617,801, Feb. 23, 1967, now abandoned, which in turn is a continuation-in-part of application Ser. No. 567,841, July 26, 1966, now abandoned. This application June 25, 1971, Ser. No. 156,931

Int. Cl. C08d 1/00; C0811 1/16; C08c 11/54 U.S. Cl. 204-159.14 17 Claims ABSTRACT OF THE DISCLOSURE The invention disclosed is for a new photocurable liquid polymer composition which includes a liquid polyene component having a molecule containing at least two unsaturated carbon-to-carbon bonds disposed at terminal positions on a main chain of the molecule, a polythiol component having a molecule containing a multiplicity of pendant or terminally positioned SH functional groups per average molecule, and a photocuring rate accelerator. The photocurable liquid polymer composition upon curing in the presence of actinic light forms odorless, solid, elastomeric or resinous products which may serve as sealants, coatings, adhesives and molded articles.

The present application for US. Letters Patents is a divisional of Ser. No. 44,607, filed June 8, 1970, which in turn is a continuation-in-part of copending application Ser. No. 617,801, filed Feb. 23, 1967, now abandoned, which in turn is a continuation-in-part of application Ser. No. 567,841, filed July 26, 1966, now abandoned.

This invention relates to a new high energy curable liquid composition which includes a liquid polyene component having a molecule containing at least two unsaturated carbon-to-carbon bonds disposed at terminal positions on a main chain of the molecule, a polythiol component having a molecule containing a multiplicity of pendant or terminally positioned SH functional groups per average molecule, and a photocuring rate accelerator.

It is well known in the art that cure of internally unsaturated polymers such as polybutadiene or polyisoprene may be effected with polythiols. However, such polymers, due mainly to residual internal unsaturation after curing, are unstable either to thermal oxidation or ultra-violet catalyzed oxidation, and are subject to rapid attack by ozone. Eventually degradation and embrittlement results in the internal double bond polymers, substantially reducing their useful service life.

A limitation of commercially available liquid polyurethane prepolymers is the fact that they are terminated by isocyanate (NCO) groups. These --NCO groups are extremely unstable in storage, and are highly water-sensitive such that under practical conditions, they react with traces of moisture from the atmosphere to form gaseous carbon dioxide and amino groupings which in turn react with more NCO to form eventually a highly viscous, sometimes completely insoluble urea-extended chain network. In cases where insolubilization occurs, the polymer has to be discarded at great expense. Further, if the NCO-terminated prepolymers come in contact with traces of either acidic or basic impurities, dimerization and/or trimerization of the NCO functions may take place to form viscous, sometimes insoluble products during storage. Even mild alkalis such as those constituents normally present on the surface of glass vessels and containers may cause storage problems.

A further limitation for some applications is found in polyurethane polymers of the prior art which are derived from aromatic diisocyanates or polyisocyanates such as tolylene-Z,4-diisocyanate, tolylene-2,6-diisocyanate, 4,4- diisocyanatodiphenylmethane, and the like. These aromatic diisocyanates (or mixtures thereof) enjoy widespread use in polyurethane elastomers, foams, and coatings, because of their ready commercial availability, high degree of reactivity and relatively low cost. The derived polyurethane products, however, are known to turn yellow, amber, orange or brown in color when exposed to sunlight, ultraviolet light or other forms of actinic radiation. This yellowing tendency imparts a definite limitation on the usage of such polyurethanes in many applications. There is evidence in the technical literature that shows that this yellowing or discoloration problem is directly attributable to the aromatic (benzeneoid) nucleus in the aromatic diisocyanates, and accordingly serious yellowing problems in polyurethanes may be avoided by use of aliphatic polyisocyanates such as hexamethylene diisocyanate. These aliphatic polyisocyanates, however, are difficult to manufacture, are relatively expensive and are relatively slow in reaction rate during polymer formation reactions in comparison to the aromatic polyisocyanates.

The use of polymeric liquid polythiol polymers which are cured to solid elastomeric products by oxidative coupling of the thiol (-SH) groups to disulfides (S-S- groups) are known in the sealants, coatings and adhesives field. oxidizing agents such as PbO' are commonly used to efiFect this curing reaction. These mercapto-containing compounds, however, both before and after curing with PbO -type curing system yield elastomeric compositions with an offensive odor which limits their usefulness generally to outdoor service. Thus, oxidatively-cured mercapto polymer systems have found restricted commercial acceptance due to their offensive odors.

A limitation of commercial liquid polymeric sealants and coatings is found in one-package systems. All the compounding ingredients, including the curing agents, are blended together and charged into a tightly sealed coutainer until used. In these commercial sealants (polysulfides, polydisulfides, polymercaptans, polyurethanes and polysilicones), the curing reaction of one-package systems is initiated by moisture (H O) from the air. The moisture-curable systems leave something to be desired because the moisture content of the air varies widely. Hence, the curing performance of moisture-curable adhesives, coatings and sealants is variable and is diflicult to predict and control. In the case of polyurethanes a further disadvantage of moisture-curable systems is observed. In the curing reaction (-NCO groups reacting with H O) a volatile gas (carbon dioxide) is liberated and this evolved gas tends to cause unsightly and property-weakening gas pockets or voids in the final product.

It has now been found that numerous defects of the prior art may be effectively overcome by practice of the present invention which provides a new photocurable liquid composition containing particular polyenes which are curable by polythiols to solid resins or elastomers. For example, when urethane-containing polyenes are compounded with polythiols, the prepared composition may be stored safely for long periods of time in the absence of actinic light. Upon exposure to actinic light such as ultraviolet light, the prepared system may be cured rapidly and controllably to a polythioether-polyurethane product which is low in cost and equal or better in reaction rate in polymer formation when compared with compositions derived from conventional technology.

Generally stated, the present invention provides a photocurable composition which comprises a particular polyene component, a polythiol component, and a photocuring rate accelerator.

The polyene component may be represented by the formula:

wherein mis an integer of at least 2, wherein X is a member selected from the group consisting of:

iii

Lil

The members (a) to (e) are connected to [A] through divalent chemically compatible derivative members. The members (a) to (e) may be connected to [A] through a divalent chemically compatible derivative member of the group consisting of Si(R)- carbonate, carboxylate, sulfone, --O,

alkyl and substituted alkyl, cycloalkyl and substituted cycloalkyl, urethane and substituted urethane, urea and substituted urea, amide and substituted amide, amine and V substituted amine, and aryl and substituted aryl. The alkyl members have from 1 to 9 carbon atoms, the aryl members are either phenyl or naphthyl, and the cycloalkyl members have from 3 to 8 carbon atoms with R and said members substituted being defined above. B is a member of the group consisting --O--, --S-, and NR.

The member [A] is polyvalent; free of reactive carbonto-carbon unsaturation; free of highly water-sensitive members; and consisting of atoms selected from the group consisting of carbon, oxygen, nitrogen, chlorine, bromine, fluorine, phosphorus, silicon and hydrogen.

The polyene component has a molecular weight in the range from about 64 to 20,000 preferably about 200 to about 10,000; and a viscosity in the range from essentially 0 to 20 million centipoises at C. as measured by a Brookfield Viscometer.

The polythiol component has a molecular weight in the range from about 50 to about 20,000 and the general formula:

wherein R is a polyvalent organic moiety free from reactive carbon-to-ca-rbon unsaturatoin and n is at least 2. The polyene/polythiol mole ratio are selected so as to provide a solid, self-supporting cured product under ambient conditions in the presence of actinic light.

More particularly, the member [A] of the polyene composition may be formed primarily of alkyl radicals, phenyl and urethane derivatives, oxygenated radicals, and nitrogen substituted radicals. The member [A] may also be represented by the formula:

mlcfistllmt l. l, l.

the present invention may be prepared as exemplified below I.POLY (ALKYLENE-ETHER) POLYOL REACTED WITH UNSA'IFURATED MONOISOCYANATES FORMING POLYURETHANE POLYENES AND RELATED POLYMERS Dlfuncttonal O /y orrrto ii- N- cm -cn om] Interconnected-modified dlfuncflonal Interconnected-modified tetrafunctlonal n L A Jn 1&7 R7 H Interconnected-modified dlfunctlonal IIl.-POLY (ALKYLENE-ETHER) POLYOL RE- ACTED WITH POLYISOCYANATE AND UN- SATURATED MONOALCOHOL FORMING POLY- URETHANE POLYENES AND RELATED POLY- MERS Difunctlonal In the above formulas, the sum of x+y+z in each chain segment is at least 1; P is an integer of l or more;

CH =CH-CH 2 hydrogen, phenyl, cycloalkyl, and alkyl.

The novel class of polyenes of this invention derived from carbon to carbon unsaturated monoisocyanates may be characterized by extreme case and versatility of manufacture when the liquid functionality desired is greater than about three. For example, consider an attempted synthesis of a polyheXene starting with an OH terminated polyalkylene ether hexol such as Niax Hexol LS- 490 (Union Carbide Corp.) having a molecular weight of approximately 700, and a viscosity of 18,720 cps. at C. An attempt toterminate this polymer with ene groups by reacting one mole of hexol with 6 moles of tolylene diisocyanate (mixed-2,4-, -2-6-isomer product) and 6 moles of allyl alcohol proceeded nicely but resulted in a prematurely chain extended and cros'slinked solid product rather than an intended liquid polyhexene. Using the monoisocyanate route, however, this premature chain extension may be avoided and the desired polyurethane-containing liquid polyhexene may be very easily prepared by a simple, one-step reaction of one mole of hexol with 6 moles of allyl isocyanate. This latter polyhexene has the added advantageof being cured using the teachings of this invention to a non-yellowing polythioether polyurethane product. Similarly, the unsaturated monoisocyanate technique may be used to prepare liquid polyenes fromother analagous highly functional polyols such as cellulose, polyvinyl alcohol, partially hydrolized polyvinyl acetate, and,

wherein R is a polyvalent organic moiety free from reactive carbon-to-carbon unsaturation and n is at least 2;

with a polyisocyanate of the general formula Rn- NCO wherein R is a polyvalent organic moiety free from reactive carbon-to-carbon unsaturation and n is at least '2 and a member of the group consisting of an ene-o1,

H=CH2 4 yne-ol, ene-amine and yne-amine. The reaction is carried out in an inert moisture-free atmosphere (nitrogen blanket) at atmospheric pressure at a temperature in the range from O to about C. for a period of about 5 minutes to about 25 hours. In the case where an ene-o1 or yne-ol is employed, the reaction is preferably a one step reaction wherein all the reactantsare charged together. In the case where an ene-amine or yne-amine is used, the reaction is preferably a two step reaction wherein the polyol and the polyisocyanate are reacted together and thereafter preferably at room temperature, the ene-amine or yne-amine is added to the NCO terminated polymer formed. The group consisting of ene-o1, yne-ol, ene-amine and yne-amine are usually added to thereaction in an amount such that there is one carbon-to-carbon unsaturation in the group member per hydroxyl group in the polyol and said polyol and group member are added in combination in a stoichiometric amount necessary to react with the isocyanate groups in the polyisocyanate.

A second general method of forming a polyene containing urethane groups (or urea groups) is to react a polyol (or polyamine) with an ene-isocyanate or an yne-isocyanate to form the corresponding polyene. The general procedure and stoichiometry of this synthesis route is similar to that described for polyisocyanates in the preceding. In this instance, a polyol reacts with an ene-isocyanate to form the corresponding polyene. It is found, however, that products derived from this route, when cured in the presence of an active light source and a polythiol, may form relatively weak solid polythioether products. To obtain stronger cured products, it is desirable to provide polar functional groupings within the main chain backbone of the polymeric polyene. These polar.

functional groupings serve as connecting linkages between multiple repeating units in the main chain series, and serve as internal strength-reinforcing agents by virtue of their ability to create strong interchain attraction forces between molecules of polymer in the final cured composition.

Polyenes containing ester groups may be formed by reacting an acid of the formula wherein R is a polyvalent organic moiety free from reactive carbon-to-carbon unsaturation and n is at least 2; with either an ene-ol or yne-ol. The reaction is carried out in an inert moisture-free atmosphere (nitrogen blanket) at atmospheric pressure at a temperature in the range from 0 to about 120 C. for a period of 5 minutes to 25 hours. Usually the reaction is carried out in the presence of a catalyst (p-toluene sulfonic acid) and in the presence of a solvent, e.g. benzene at refluxing temperature. The water formed is azeotroped off of the reaction.

Another method of making an ester containing polyene is to react a polyol of the formula of this invention. These activated ene compounds are very prone to self-polymerization reactions to form vinyl polymers. Excessive amounts of self-polymerization of the ene groups is an undesirable side reaction in the present invention since the desired polythioether reaction products are precluded whenever self-polymerization of the ene groups occurs. Finally, the presence of activated, easily self-polymer-izable ene groups in the composition leads to oxygen inhibition during curing, storage stability problems, or the need for excessively high inhibitor concentrations.

In forming the urethane-containing polyenes of the present invention, catalytic amounts of a catalyst may be employed to speed up the reaction. This is especially true in the case where an ene-o1 is used to form the polyene. Such catalysts are well known to those in the art and include organometallic compounds such as stannous octoate, stannous oleate, dibutyl tin dilaurate, cobalt acetylacetonate, ferric acetylacetonate, lead naphthanate and dibutyl tin diacetate.

In summary, by admixing polyenes or polyynes containing two or more reactive unsaturated carbon-to-carbon bonds located terminal from the main chain with a polythiol containing two or more thiol groups per molecule and thereafter exposing said liquid mixture having photocuring rate accelerator to actinic light, there is provided an essentially odorless solid elastomeric or resinous polymeric product.

Polythiol as used herein refers to simple or complex organic compounds having a multiplicity of pendant or terminally positioned -SH functional groups per average molecule.

On the average the polythiol must contain 2 or more -SH groups/molecule and have a viscosity range of 68- sentially to million centipoises (cps) at 70 C. as measured by a Brookfield Viscometer either alone or when in the presence of an inert solvent, aqueous dispersion or plasticizer. Operable polythiols in the instant invention usually have molecular weights in the range about 50 to about 20,000, and preferably from about 100 to about 10,000.

The polythiols operable in the instant invention may be exemplified by the general formula Rs \SH n where n is at least 2 and R is a polyvalent organic moiety free from reactive carbon-to-carbon unsaturation. Thus R may contain cyclic groupings and hetero atoms such as N, P or O and primarily contains carbon-carbon, carbonhydrogen, carbon-oxygen, or silicon-oxygen containing chain linkages free of any reactive carbon-to-carbon unsaturation.

One class of polythiols operable with polyenes to obtain essentially odorless polythioether products are esters of thiol-containing acids of the formula HSR COOH where R is an organic moiety containing no reactive carbon-to-carbon unsaturation with polyhydroxy compounds of structure where R is an organic moiety containing no reactive carbon-to-carbon unsaturation, and n is 2 or greater. These components will react under suitable conditions to give a polythiol having the general structure:

0 R u-\Oi JR SH) where R and R are organic moieties containing no reactive carbon-to-carbon unsaturation, and n is 2 or greater.

Certain polythiols such as the aliphatic monomeric polythiols, ethane dithiol, hexamethylene dithiol, decamethylene dithiol, tolylene-2,4-dithiol, and the like, and some polymeric polythiols such as a thiol-terminated ethylcyclohexyl dimercaptan polymer, and the like, and similar polythiols which are conveniently and ordinarily synthesized on a commercial basis, although having obnoxious odors, are operable but many of the end products are not widely accepted from a. practical, commercial point of view. Examples of the polythiol compounds preferred because of relatively low odor level include but are not limited to esters of thiogylcolic acid (HSCH COOH), a-mercaptopropionic acid (HSCH(CH )COOH and B-mercaptopropionie acid (HSCH CH COCH) with polyhydroxy compounds such as glycols, triols, tetraols, pentaols, hexaols, and the like. Specific examples of the preferred polythiols include but are not limited to ethylene glycol bis (thioglycolate), ethylene glycol bis (fit-mercaptopropionate), trimethylolpropane tris (thioglycolate), trimethylolpropane tris (fl-mercaptopropionate), pentaerythritol tetrakis (thioglycolate) and pentaerythritol tetrakis (fl-mercaptopropionate), all of which are commercially available. A specific example of a preferred polymeric polythiol is polypropylene ether glycol bis (fl-mercaptopropionate) which is prepared from polypropylene-ether glycol (e.g. Pluracol P2010, Wyandotte Chemical Corp.) and B-mercaptopropionic acid by esterification.

The preferred polythiol compounds are characterized by a low level of mercaptan-like odor initially and after reaction, given essentially odorless polythioether end products which are commercially attractive and practically useful resins or elastomers for both indoor and outdoor applications.

Prior to curing, the curable liquid polymer may be formulated for use as solids, or disposed in organic solvents, or as dispersions or emulsions in aqueous media.

The curable liquid polymer compositions prior to curing may readily be pumped, poured, siphoned, brushed, sprayed, doctored, or otherwise handled as desired. Following application, curing in place to a solid resin or elastomer may be effected either very rapidly or extremely slowly as desired by manipulation of the compounding ingredients and the method of curing.

The liquid polythioether-forming components and compositions, prior to curing, may be admixed with or blended with other monomeric and polymeric materials such as thermoplastic resins, elastomers or thermosetting resin monomeric or polymeric compositions. The resulting blend may be subjected to conditions for curing or c0- curing of the various components of the blend to given cured products having unusual physical properties.

Although the mechanism of the curing reaction is not completely understood, it appears most likely that the curing reaction may be initiated by most any actinic light source which dissociates or abstracts a hydrogen atom from an SH group, or accomplishes the equivalent thereof. Generally the rate of the curing reaction may be increased by increasing the temperature of the composition at the time of initiation of cure. In many applications, however,

the curing is accomplished conveniently and economically by operating at ordinary room temperature conditions. Thus for use in elastomeric sealants, it is possible merely to photoexpose the polyene, polythiol, photocuring rate accelerator admixture to ambient conditions and obtain a photocured solid elastomeric or resinous product.

By proper choice of type and concentration of photocuring rate accelerator for initiation, the curing period required for'conversion of the polyene/polythiol composition from theliquid to the solid state may be varied greatly as. desired. In combination with suitable accelerators or retarders, the curing period may vary from about a second or less to about 30 days or more. In general, short curing periods are achieved in applications where thin films of curable. composition are required, such as in the field of coatingswhereas the'long curing periods are achieved and desired where more massive layers of composition are required, such as inthe field of elastomeric sealants.

A class of actinic light useful herein is ultraviolet light and other forms of actinic radiation which are normally found in radiation emitted from the sun or from artificial sources such asType RS Sunlamps, carbon arc lamps, xenon arc lamps, mercury vapor lamps, tungsten halide lamps and the like. Ultraviolet radiation. may be used most efficiently if the protocurable polyene-polythiol composition contains a suitable photocuring rate accelerator. Curing periods may be adjusted to be very short and hence commercially economical by proper choice of ultraviolet source, photocuring rate accelerator and concentration thereof, temperature and molecular weight, and reactive group functionality of the polyene and polythiol. Curing periods of less than about 1 second duration are possible, especially in thin film applications such as desired for example in coatings and adhesives.

Conventional curing inhibitors or retarders which may be used in order to stabilize the components or curable compositions so as to prevent premature onset of curing may include hydroquinone; p-tert.-butyl catechol; 2,6-di tert. butyl p-methylphenol; phenothiazine; N-phenyl-2- naphthylamine; inert gas atmospheres such as helium, argon, nitrogen and carbon dioxide; vacuum; and the like.

It is understood to be within the scope of this invention that the photocuring rate accelerator may be present as a separate and distinct component such as azobenzene, as a mixture of two or more separate components, such as benzophenone; benzanthrone; anthrone; and .dibenzosuberone; carbon tetrachloride and phenanthrene; and the like,- or in a chemically combined form within the molecularstructure of either the polyene or the polythiol. An example of this latter condition wherein the photocuring rate accelerator is present not as a separate component, but rather. in a form chemically combined within the polyene component is the following structure which contains four reactive carbon-to carbon unsaturated groupings and. one diaryl ketone grouping per. average molecule.

O CH2GH=CHI none, 4 morpholinobenzophenone, 4'-morpholindeoxybenzoin, p diacetylbenzene, 4-aminobenzophenone, 4'- methoxyacetophenone, benzaldehyde, u-tetralone, 9-acettylphenanthrene, 2 acetylphenanthrene, IO-thioxantheonen, 3-acetylphenanthrene, 3-acetylindole 1,3,5-triacetylbenzene, and the like including blends thereof, to greatly reduce the exposure times.

The curing rate accelerators are usually added in an amount ranging from about 0.0005 to about 50% by weight of .the photocurable composition, with a preferred range being from about 0.05 to about 25% by weight. Preferred photocuring rate accelerators are the aldehyde and ketone carbonyl compounds having at least one aromatic nucleus attached directly to the group.

To obtain the maximum strength, solvent resistance, creep resistance, heat resistance and freedom from tackiness the reaction components consisting of the polyenes and polythiols of this invention are formulated in such a manner as to give solid, crosslinked, three dimensional network polythioether polymer systems on curing. In order to achieve such infinite network formation the individual polyenes and polythiols must have a functionality of at least 2 and the sum of the functionalities of the polyene and polythiol components must always be greater than 4. Blends and mixtures of the polyenes and the polythiols containing said functionality are also operable herein.

The compositions to be cured, i.e. (converted to soild resins or elastomers) in accord with the present invention may, if desired, include such additives as antioxidants, accelerators, dyes, inhibitors, activators, fillers, pigments, anti-static agents, flame-retardant agents, thickeners, thixotropic agents, surface-active agents, viscosity modifiers, extending oils, plasticizers, tackifiers and the likewithin the scope of this invention. Such additives are usually preblended with the polyene or polythiol prior to or during the compounding step. Operable fillers include natural and synthetic resins, carbon black, glass fibers, wood flour, clay, silica, alumina, carbonate, oxides, hydroxides, silicates, glass flakes, glass beads, borates, phosphates, diatomaceous earth, talc, kaolin, barium sulfate, calcium sulfate, calcium carbonate, antimony oxide and the like. The aforesaid additives may be present in quantities up to 500- parts or more per parts polymer by weight and preferably about 0.0005 to about 300 parts on the same basis.

The compounding of the components prior to curing may be carried out in several ways. For example, the polyene, the polythiol and any other additives may be admixed and charged to an aerosol can, drum, tube, or cartridge for subsequent use.

Another useful method of compound is to prepare in an ambient atmosphere by conventional mixing techniques but in the absence of actinic radiation a composition consisting of polyene, antioxidant (to inhibit spontaneous oxygen-initiated curing), polythiol, UV sensitizer or photoinitiator, and other inert additives. This composition may be stored in the dark for extended periods of time, but on exposure to actinic radiation (e.g., ultraviolet light, sunlight, etc.) will cure controllably and in a very short time period to solid polythioether products.

The mole ratio of ene/thiol groups for preparing the curable composition is from about 0.2/1 to about 5/ 1, and desirability about .75/1 to about 1.5/1 group ratio.

13 The following examples will aid in explaining, but should not be deemed as limiting, the instant invention. In all cases, unless otherwise noted, all parts and percentages are by weight.

FORMATION OF POLYENE PREPOLYMER Example 1 458 g. (0.23 mole) of a commercially available liquid polymeric diisocyanate sold under the trade name Adiprene L-100 by E. I. du Pont de Nemours & Co. was charged to a dry resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer, and gas inlet and outlet. 37.8 g. (0.65 mole) of allyl alcohol was charged to the kettle and the reaction was continued for 17 hours with stirring at 100 C. Thereafter the nitrogen atmosphere was removed and the kettle was evacuated 8 hours at 100 C. 50 cc. dry benzene was added to the kettle and the reaction product Was azeo troped with benzene to remove the unreacted alcohol. This allyl terminated liquid prepolymer had a molecular weight of approximately 2100 and will be referred to as Prepolymer A hereinafter.

Example 2 400 g. (0.2 mole) of Adiprene L-100 was charged to a dry resin kettle maintained under nitrogen and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. 25.2 g. (0.43 mole) of propargyl alcohol (HCEC-CH OH) was added to the kettle and the reaction was continued with stirring for 18 hours at 160 C. Thereafter the nitrogen atmosphere was removed and the kettle was evacuated 16 hours at 100 C. followed by azeotropic distillations with 50 cc. water and then 50 cc. benzene to remove any excess propargyl alcohol. This I-ICzC- terminated liquid prepolymer had a viscosity of 27,500 centipoises at 70 C. and a molecular weight of 2100 and will be referred to as Prepolymer B hereinafter.

Example 3 1 mole of commercially available poly(ethylene ether) glycol having a molecular Weight of 1450 and a specific gravity of 1.21 was charged to a resin kettle maintained under nitrogen and equipped with a condenser, stirrer, thermometer and a gas inlet and outlet. 2.9 g. dibutyl tin dilaurate as a catalyst was charged to the kettle along with 2 moles tolylene-2,4-diisocyanate and 2 moles of allyl alcohol. The reaction was continued with stirring at 60 C. for 2 hours. Thereafter a vacuum of 1 mm. was applied for 2 hours at 60 C. to remove the excess alcohol. This CHFCH terminated prepolymer had a molecular weight of approximately 1950 and will hereinafter be referred to as Prepolymer C.

Example 4 1 mole of a commercially available poly(propylene ether) glycol having a molecular weight of about 1958 and a hydroxyl number of 57.6 was charged to a resin kettle equipped with a condenser, stirrer, thermometer and a gas inlet and outlet. 4 g. of dibutyl tin dilaurate as a catalyst was added to the kettle along with 348 g. (2.0 moles) of tolylene-2,4-diisocyanate and 116 g. (2 moles) of allyl alcohol. The reaction was carried out for 20 minutes at room temperature under nitrogen. Excess alcohol Was stripped from the reaction kettle by vacuum over a 1 hour period. The thus formed CH =CH- terminated liquid prepolymer had a molecular weight of approximately 2400 and will hereinafter be referred to as Prepolymer D.

Example 5 750 g. of a N-containing tetrol (hydroxyl functionality ==4) available from Wyandotte Chemicals Corp. under the trade name Tetronic Polyol 904 having a M.W.

14 of 7,500 was placed in a reaction vessel heated at 110 C. The flask was maintained under vacuum for 1 hour. Then, under an atmosphere of nitrogen, 0.1 cc. dibutyl tin dilaurate was added and the flask was cooled to 50 C. Now 18.3 g. allyl isocyanate was added slowly, maintaining the temperature at about C. for about 1 hour after the addition was completed. The thus formed polymeric polyene (i.e., Prepolymer E hereinafter) had a theoretical allyl functionality of 2.2, a theoretical hydroxyl functionality of 1.8, and a calculated molecular weight of about 7,683.

Example 6 To a resin kettle maintained under a nitrogen atmos phere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet was added 843 g. of a commercially available liquid diisocyanate prepolymer sold under the trade name Multrathane F-196 by Mobay Chemical Co., said prepolymer having a molecular weight of about 1680 and an available isocyanate content of 4.7- 5.2%. 87 g. (1.5 moles) of allyl alcohol was added to the kettle and the reaction was continued for 18 hours at 140 C. with stirring. Thereafter the nitrogen atmosphere was removed and the kettle was evacuated for 22 hours at C. 50 cc. of dry benzene was added to the :kettle and the reaction product was azeotroped therewith to remove any untreated alcohol. This CH =CH terminated liquid prepolymer had a viscosity of 25,000 centipoises at 70 C. and a molecular weight of approximately 1800 and will be referred to as Prepolymer F hereinafter.

Example 7 678 g. (0.34 mole) of a commercially available poly (propylene ether) glycol sold under the trade name NIAX by Union Carbide Co. and having a molecular weight of about 2025 was degassed for 2 hours at 100 C. and thereafter charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. 118 g. (0.68 mole) of tolylene 2,4-diisocyanate was charged to the kettle and the reaction was heated with stirring for 2% hours at 120 C. After cooling 58 g. (1.0 mole) of allyl alcohol was added to the kettle and the mixture was refluxed at 120 C. for 16 hours under nitrogen. Excess allyl alcohol was removed overnight by vacuum at 100 C. Half of the allyl terminated liquid prepolymer having a viscosity of 19,400 cps. at 30 C. as measured on a Brookfield Viscometer was removed from the kettle and will be referred to hereinafter as Prepolymer G. The other half portion of the prepolymer was combined with 50 cc. of dry benzene and azeotroped overnight following which excess benzene was pulled out under vacuum for 5 hours at 120 C. This portion of the allyl-terminated liquid prepolymer had a viscosity of 15,600 cps. at 70 C. as measured on a Brookfield Viscometer and a molecular weight of approximately 2500 and will hereinafter be referred to as Prepolymer H.

Example 8 751 g. (0.38 mole) of a commercially available poly (propylene ether) glycol sold under the trade name Pluracol P 2010 by Wyandotte Chemical Co. was degassed at room temperature for 3 hours and then charged to a dry resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. 132 g. (0.76 mole) of tolylene- 2,4-diisocyanate was charged to the kettle and the kettle was heated for 2 hours at 120 C. with stirring under nitrogen. After cooling 58 g. 1.0 mole) of allyl alcohol was added and the mixture was refluxed at 120 C. overnight. Excess allyl alcohol was stripped by vacuum overnight at 120 C. The thus formed allyl terminated liquid prepolymer had a viscosity of 15,000 cps. as measured on a Brookfield Viscometer at 70 C. and a molecular weight of approximately 2500 and will hereinafter be referred to as Prepolymer 'I.

Example 9 To a 1 liter resin kettle equipped with stirrer, thermometer, gas inlet andvoutlet and heated to a temperature of 50, C. was charged 610 g- (0.2 mole) of poly(tetramethylene ether) glycol, commercially available from.

Quaker Oats Co. and. having a hydroxyl number of 37.1 along with 0.3 g. dibutyl tin dilaurate. The temperature of the kettle was raised to 110 C. and the contents were .freed ofwater under 1 millimeter. vacuum for 1 hour. The resin kettle was cooled to 60 C. and the system was placed under a protective atmosphere of nitrogen throughout the remainder of the reaction. 25.2 g. of allyl isocyanate (0.4 mole) was added dropwise to the kettle at such a rate as to maintain the temperature at 60 C. When the NCO content dropped to 0.54 mg./g., 1 mm. vacuum again was applied and the system was heated at 70 C. for one hour. The thus formed polymer product was a solid at room temperature but at 50 C. isclear and pourable. The polymer product had a viscosity of. 1,800 centipoises at 70 C. as measured on a Brookfield viscometer and an average molecular weight of approximately 3200.

Example 10 To a 1 liter resin kettle equipped with stirrer, thermometer, gas' inlet and outlet was charged 591 g. (0.30 mole) of a.poly(propylene ether) glycol commercially available from Union Carbide under the trade name PPG 2025 and 0.3 g. of dibutyl tin dilaurate. The kettle was heated to 110 C.,and the contents were freed of water under 1 mm. vacuum for 1 hour. The kettle was cooled to C. and the system was placed under a protective atmosphere of nitrogen throughout the remainder of the reaction. 53.1 ml. (49.8 g., 0.6 mole) of allyl isocyanate commercially available from Chemetron Corp. was added to the system. An exotherm carried the temperature-to 45 C. in 22 minutes. After 60 minutes, the NCO content (as determined by titration) was 0.04 mg./g. ,The system was placed under 1 mm. vacuum and heated-t0 70 C. to remove traces of unreacted allyl isocyanate. The resultant polymer product had a viscosity of 600 centipoises at C. as measured on a Brook-field Viscometer and an average molecular weight of approximate,

The next two examples show a method of preparing the polyenes of the instant invention by dehydration of polyether glycols.

Example 11 100 g. of poly(propylene ether) glycol commercially available from Union Carbide under the trade name PPG 2025 waspoured through a hot tube filled with aluminum oxide at such a rate that the entire reaction took place in 2 hours. The tube was 1" in diameter with the reaction zone 1 ft. long and completely enclosed within a tube furnace. The alumina catalyst was 10-18 mesh and was maintained at 350 C. using a Lindberg I-Ievi-Duty tube furnace. The tube was fitted with a dropping funnel and a nitrogen inlet at the top. Nitrogen pressure was kept on the systemv throughout the reaction. The product collected from the bottom of the tube was analyzed for unsaturation by the mercuric acetate titration method and was found to have 100% of the theoretical amount of unsaturation expected after dehydration of both terminal hydroxyl groups of the poly(propylene ether) glycol. The polyene product had a viscosity of 125 cps. at 70 C. and an average molecular weight of approximately 2000.

Example :12

1 kilogram of poly(propylene ether) glycol commercially available from Union Carbide under the trade name PPG. 2025 was heated to 120 C. in a round bottom flask. To this was added 120 ml. (20% excess) of acetic anhydride at such a rate that the temperature of the mixture was kept at 120-140 C. Following the.

addition, the mixture was heaed at 140C. for 4 hours. It was then cooled and diluted with an equal volume of chloroform, washed with 10% aqueous sodium carbonate, then with water. The organic layer was separated and the chloroform was removed by distillation. Infrared analysis of the purified material showed it to be the di acetate of the poly(propylene ether) glycol with no residual hydroxy groups.

100 g. of this diacetate wasput through the hot tube as in Example 11 except that the packing was glass helices instead of alumina and the temperature was 375 C. The product contained 64% of the theoretical amount of unsaturation expected after the elimination of acetic acid from both terminal acetoxy groups of the poly (propylene ether) glycol diacetate.

Example 513 114 g. of hexol sold under the trade name NIAX polyol LS490 by Union Carbide Chemicals Co. having a molecular Weight of 684 was charged to a 1 liter 4 neck flask and heated to 110 C. under vacuum and nitrogen for 1 hour. It was then cooled to approximately 60 C. whereat 0.1 cc. of dibutyl tin dilaurate was added followed by slowly adding 83 g. (1 mole) of allyl isocyanate to keep the temperature in the range 70-80" C. during the addition. After addition, the reaction was allowed to continue for 1 hour at 70 C. The polymeric hexaene product obtained had an average molecular weight of approximately 1200 and a viscosity of 300 centipoises at 70 C.

Example 14 To a 1 liter- 4 neck flask was charged 300 milliliters of dimethylformamide, 35 g. of tolylene-2,4-diisocyanate and 0.1 cc. of dibutyl tin dilaurate. A mixture of 11.6 g. of allyl alcohol and 22.8 g. of hexol commercially available from Union Carbide Chemical Co. under the trade name NIAX Polyol 118-490 having a molecular weight of 684 was slowly added to the flask. Temperature was kept at approximately 65 C. during the addition and for a period of 1 hour. :The polymeric product obtained had an average molecular weight of approximately 2100.

Example 15 To a 1 liter 4 neck flask was charged 100 cc. of dimethylformamide, 100 g. of tolylene-2,4-diisocyanate and 0.1 cc. dibutyl tin dilaurate. 58 g. of hexol, i.e. NIAX Polyol LS-490 by Union Carbide and 34 g. of allyl alcohol were mixed together and added dropwise to the flask. Before the addition to the flask was completed, the reaction,-which was exothermic, jelled and the addition was discontinued.

A comparison of Examples 13, 14 and 15 shows that Example 13 is an improvement over Examples 14 and 15 in that it allows one to form polymer without the necessity of a solvent. A comparison of Examples 14 and 15 shows that when starting with a highly functional polyol using the diisocyanate/allyl alcohol technique one must operate in dilute solution to avoid premature crosslinking (i.e., gelation) which renders the polyene product useless as a curable liquid prepolymer. This problem is avoided completely by using the unsaturated monoiso-, cyanate technique illustrated in Example 13.

Example 16 In a 1 liter, 4 neck flask'220 g. hexol commercially available from Union Carbide ChemicalsCo. under the tradename NIAX Polyol LS-490 (0.32 mole) and 0.1 cc. of dibutyl tin dilaurate was heated to 110 C. under vacuum for 1 hour. After cooling in nitrogen to approximately 60 C., g. of allyl isocyanate was addedto the flask by means of a dropping funnel. The exothermic reaction produced a temperature of C. When the addition was complete the reaction was continued at 70 C. for 1 hour. The resulting triene polymer 17 18 product had an average molecular weight of approxi- Example 21 mately 950 and a viscosity of 300 centipoises as measd on a B kfi ld Viscometer at 70 C, A crotyl-terminated polyurethane which contains two Exam 1e 17 reactive double bonds per average molecule in a near p terminal position was prepared following the general To a 1 liter 4 neck flask was charged 300 g. of a polyprocedure of Example 3. The resulting polymeric polyene ester diol (molecular weight 3232) sold under the trade was found to have the following formula:

name RC Polyester S 101-35 by R. C. Division, Hooker Example 22 Chemical Corp. and 0.1 cc. of dibutyl tin dilaurate. The Following the pmmdure of Ex am P16 3 and using flask was heated to 110 C. of dibutyl tin dilaurate. The p flask was heated to under vacuum and main necessary reactants, a polyene of the following formula was prepare tained thereat for 1 hour. The flask was cooled to ap- 25 proximately 60 C., nitrogen was admitted, and 7.7 g. allyl isocyanate and 8.1 g. of tolylene-2,4-diisocyanate was added by means of a dropping funnel to the reaction C at a moderate rate. A maximum temperature of 90 C. was needed. When the addition was complete the reaction 0 l was allowed to continue at 70 C. for 1 hour. The thus CH;OH=CHCH;O- -NH NH-(l-0-(C,H|O)--- formed solid polymeric product had an average molecular L J weight of approximately 6800 and a viscosity of 13,600 2 centipoises when measured on a Brookfield Viscometer CH at 70 C.

Example 18 To a 1 liter 4 neck flask heated at 110 C. was charged 808 g. of a polyester diol (having a molecular weight 3232) sold under the trade name RC Polyester S 101-35 by RC. Division Hooker Chemical Corp. and 0.1 cc. dibutyl tin dilaurate. The flask was maintained under vacuum at 110 C for 1 hour. The flask was cooled to approximately 50 C. and with nitrogen passing through,

a mixture of 10 g. of allyl alcohol and 60 g. of tolylene- 2,4-diisocyanate was added via a dropping funnel at a moderate rate. The reaction was allowed to continue for 15 minutes. A maximum temperature of 90 C. was produced by the exothermic reaction. The polymeric CH; product obtained was a solid at room temperature but liquid at 70 C. The product had an average molecular O 0 0 weight of approximately 10,500 and a viscosity of 270,000 cH,=on-cn.-oll Nn-.|- NH-ti-o-(empd-il centipoises at 70 C. NH

Example 23 Following the procedure of Example 3, and using necessary reactants, a polyene of the following formula was prepared:

1 Example 19 Following the procedure of Example 12 and using necessary reactants, a polyene of the following formula was prepared:

s 5 a e"- 35 a s 60 CH; N

Example 20 0 o 0 l Following the procedure of Example 3, and using CHQ=CH-CHIO NH NH-lL-O-(CHOO- necessary reactants, apolyene of the following formula. was prepared:

(IIH: $113 TABLE-Continued Component [B] None.

DDI Diisocyanate Dimer acid-based dllsocyanate, General Mills 00., 2 moles.

C 3 CHzH-OH OCNCH CH; CH;NCO NCH4CH;-N (in, CH,CHOH 2, 7-dl(lsocyanato)-heptane, 4 moles. O N, N, N, N'-tetrakls (2-hydroxypropyD-ethylene diamlne, Wyan- Component [A] HO CHQCHQO H /aan Ply(ethylene ether) glycol, 1 mole.

1 mole.

H O-C HCH2 BIO-(i3 H-C H: C H;

dotte Co., Quadrol, 1 mole.

Example N0.

41-.."-.... Pluracol 208 Phosphorus-based polyol, Wyandotte Chem. 00.,

PHOTO CURING PROCESS Example 43 Example 43 was repeated except that 0.0033 mole of trimethylolpropane tris (,B-mercaptopropionate) having a molecular weight of 398 was used. The mixture, upon photocuring formed a solid, odorless, self-supporting, cured elastomeric polythioether polymer.

Example 45 0.005 mole of the allyl-terminated liquid Prepolymer E was charged to a 2 oz. glass jar along with a stoichiometric amount of a polythiol to react with the allyl groups in Prepolymer E, 0.0036 mole of trimethylolpropane tris (fi-mercaptopropionate), and 2% total weight of benzophenone. The liquid reactants were stirred together briefly at room temperature and allowed to stand under ambient conditions. After exposure to ultraviolet light, a solid, odorless, self-supporting, cured elastomeric polythioether polymer resulted.

Example 46 Example 45 was repeated except that 0.0027 mole of pcntaerythritol tetrakis p-mercaptopropionate) was substituted for the trimethylolpropane tris (B-mercaptopropionate). After photocuring a cured solid, odorless, self-supporting, elastomeric polythioether polymer resulted.

Example 47 0.005 mole of the HCEC terminated liquid Prepolymer B was charged to a 2 02. glass jar along with a stoichiometric amount to react with the HCEC-- groups in Prepolymer B of trimethylolpropane tris (fi-mercaptopropionate) (0.0033 mole), and 2% total weight of 50 benzophenone. The reactants were stirred together and after photoexposure to ultraviolet light, a cured solid, odorless, self-supporting, elastomeric polythioether polymer resulted.

Example 48 0.005 mole of the allyl-terminated liquid Prepolymer F was charged to a 2 oz. glass jar along with a stoichiometric amount to react with the allyl groups of the prepolymer, i.e. 0.0033 mole of trimethylolpropane tris 6O (,B-mercaptopropionate) having a molecular Weight of 398, and 2% total weight of benzophenone. The liquid reactants were stirred together. Thereafter the reactants were photocured under ambient conditions. The reactants formed a solid, odorless, self-supporting, cured elastomeric polythioether polymer.

The following examples in Table I show curing by ultraviolet light. In all the examples in Table I, 10 g. of the allyl-terminated liquid polyene prepolymers were charged to an open glass jar to which was added a stoichiometric amount of a polythiol necessary to react with the allyl groups of the prepolymer and any UV sensitizer or activator employed. The reactants were stirred briefly and then placed outdoors for indirect photoexposure to the sunlight. Examples were checked periodically to determine the extent of cure.

TABLE I Polyene Polyene: pre- Polypolythiol, U'Vaccel- Example No. polymer thiol 1 mole ratio UV accelerator orator (g.) Curing observations G P-33 1 66 None Cured to an odorless solid in4 wks. G Q-43 1:0. do Cured to an odorless solid in 1 wk. G P433 1 :0. Acetone 0. 2 Do.

G Q,-43 1:0. 5 do 0. 2 Cured to an odorless solid 1n 1 day. G Q,43 1 0. 5 Methyl ethyl ketone- 0. 2 Cured to an odorless S0l1d in 4 days H Q-43 1 0.6 Aeetophenone 0.5 Curedin 1 hr.

H Q-43 1:0. 5 Cyolohexanone 0. 5 Outed in 3 hrs.

H 1 -38 1 0 5 Acetophenone" 0. 5 Cured in 1 hr.

I Q-43 1 0 5 do 0. 5 Cured to an odorless solid in minutes. I Q43 1 0 5 o 0.5 'No cure in 19 hrs. in dark room.

l P-33 =,.'Irimethyl0lpropane tris (d-mercaptopropionate) Q43=Pentaerythritol tetrakis (B-mercaptopropionate).

Example 5 9 1510 g. of a commercially available polyoxypropylene glycol solid under the trade name Pluracol P 2010 by Wyandotte Chemical Corp. was charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. The reactant, was degassed at room temperature for 3 hours. 265.4 g. of an 80-20% isomer mixture of tolylene-2,4-diisocyanate and tolylene-2,6-diisocyanate respectively sold under the trade name Mondur TD 80 was charged .to the kettle and the kettle was heated for 2 hours at 120 C. with stirringunder nitrogen. Thereafter, 116.9 g. (2 moles) of allyl alcohol was added to the kettle and the mixture was refluxed for 16 hours at 120 C. Excess allyl alcohol was stripped by vacuum at 115 C. for 23 hours. The thus-formed CH =CH terminated polyene prepolymer had a molecular weight of approximately 2460-2500, and a viscosity of 16,000 cps. as meas ured on a Brookfield Viscometer at 30 C.

0.005 mole of thethus-formed polyene prepolymer were charged to a 2 oz. glass jar along with a stoichiometric amount of the polymeric dithiol prepared in Example. 65. 0.5 g. of acetophenone (a UV photoinitiator) was charged to the glass jar and the mixture was immediately stirred. Thereafter the mixture was placed outdoors for UV curing. In M hours a solid, self-supporting, odorless, cured elastic polymer resulted.

Example 60 4.5 g. (0.02 mole) diallyl adipate Was charged to a 2 oz. glass bottle along with a stoichiometric amount of a polythiol to react with the CH =CH- groups in the dially adipate, i.e. 4.9 g. (0.01 mole) of pentaerythritol tetrakis (B-mercaptopropionate) and 0.2 g. of acetophenone (a UV sensitizer). The reactants were stirred briefly and then placed outdoors in the sunlight at ambient conditions. A self-supporting, solid, odorless, cured polythioether polymer resulted in less than 30 minutes.

Example 61* Example 60 was. repeated except that 0.02 mole of diallyl phthalate was substituted for the diallyl adipate. A self-supporting, solid, -odorless, cured polythioether polymer product resulted in less than 1 hour.

Example 62 Example 60 was repeated except that 0.02 mole of diallyl succinate was substituted for the diallyl adipate. A self-supporting, solid, odorless, cured polythioether product resulted in 30 minutes.

Example 63 Example 60 was repeated except that 0.02 mole of 2,2-diallyloxypropane was substituted for the diallyl adipate. .A self-supporting, solid, odorless, cured polythioether polymer product resulted in less than 1 hour.

Example 64 1.9 g. (0.02 mole) diallyl amine was charged to a 2 oz. glass bottle along with a stoichiometric amount of polythiol to react with the vinyl groups in the diallyl amine, i.e. 4.9 g. (0.01 mole) of pentaerythritol tetrakis (fi-mercaptopropionate) and 0.5 g. acetophenone (a UV activator). The reactants were stirred briefly and placed outdoors in the sunlight under atmospheric conditions. In less than 15 minutes a self-supporting, solid, odorless, cured, clear, rubbery polythioether polymer resulted.

The following shows another example of the curing of a polymeric thiol-containing compound and a vinyl-terminated polymer.

Example 65 1.5 moles of fi-mercaptopropionic acid, 0.5 mole of a commercially available poly(propyleue ether) glycol sold under the trade name Pluracol P-2010 by Wyandotte Chemical Corp. and 0.1 g. p-toluenesulfonic acid and 50 ml. benzene were charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. The mixture was heated and the benzene-water azeotrope was collected. The actual amount of water collected amounted to 17.5 g. The reaction was vacuum-stripped for several hours at 70 C. to remove benzene. The resulting polythiol polymer had a molecular weight of about 2210-2230 and an average functionality of 2 and was collected for use herein.

659 g. (0.145 mole of a poly(propyleue ether) triol commercially available from 'Wyandotte Chemical Corp. under the trade name Pluracol TPE 4542 having a molecular weight of about 4500 and a hydroxyl number of 37.1, and 0.3 g. of dibutyl tin dilaurate were charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. The reactants were maintained at 110 C. for 1 hour and then cooled under nitrogen to room temperature. 25.2 g. (0.435 mole) of allyl alcohol was added to the kettle followed by 75.7 g. (0.435 mole) of an 20% isomer mixture of tolylene-2,4-diisocyanate and tolylene 2,6-diisocyanate respectively sold under the trade name *Mondur TD 80. The temperature reached 55 C. in 6 minutes. A sample was titrated for NCO resulting in 6.02 mg. NOO/ g. after 20 minutes. After 1 hour the NCO titration showed 0.997 mg. NCO/ g. The polyene polymer had a molecular weight of about 5200 and an average functionality of 3 and was vacuum stripped at 70 C. for 1 hour and then collected. 0.003 mole of the polythiol polymeric material formed supra were charged to a 2 oz. glass jar along with 0.002 mole of the allyl-terminated polyene polymer formed herein and 0.5 g. acetophenone. The reactants were stirred briefly and then placed outdoors under atmospheric conditions. In /2 hour a self-supporting, solid, odorless, clear, cured polythioether polymer product resulted.

29 Example 66 3 g. of a linear saturated hydrocarbon backbone ethylene/propylene/non-conjugated diene terpolymer commercially available under the trade name Nordel by E. I. du Pont de Nemours Co. which had been visbroken until it had a reduced specific viscosity of 0.99 and contained 0.4 vinyl, 6.4 trans and 0.4 vinylidene unsaturated groups per 1000 carbon atoms, was dissolved in 100 ml. of benzene in a glass jar. A 50% excess over the stoichiometric amount, i.e. 0.0006 mole (0.3 g.) of pentaerythritol tetrakis(/3-mercaptopropionate) was added to the jar in addition to 0.5 g. acetophenone. The glass jar was placed in the sunlight outdoors under atmospheric conditions. After 24 hours the benzene had substantially evaporated leaving a gelatinous polymeric precipitate. Acetone was added to precipitate more polymer. The polymer was tfiltered off, washed with acetone and dried in a vacuum oven at 60 C.

2.3 g. of the above polythioether polymer product was extracted with benzene along with a control" sample of the starting visbroken Nordel material. The control sample showed a gel content (benzene insoluble) of 3.4% whereas the cured (crosslinked) solid polythioether polymer product had a gel content of 82.8%.

Example 67 0.5 mole of a carboxyl-terminated polyisobutylene, commercially available from Enjay Chemical Co. having a molecular weight of about 1800, 0.1 g. of p-toluenesulfonic acid catalyst, 1.5 moles of allyl alcohol were charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. The mixture was heated at reflux for 2 hours, then 50 ml. benzene added and the benzene-water azeotrope was collected. The actual amount of water collected amounted to 17.5 g. The reaction was vacuum stripped for several hours at 70 C. to remove benzene and any unreacted allyl alcohol.

0.005 mole of the thus formed polyene (9.6 g.), 0.0025 mole (1.2 g.) of pentaerythritol tetrakis(p-mercaptopropionate) and 0.5 g. of aceptophenone were charged to a 2 02. glass jar and briefly stirred. The jar was placed outdoors under ambient conditions. After V2 hour, a selfsupporting, solid, odorless, cured elastomeric product resulted.

Example 68 643 g. (0.32 mole) of a commercially available poly- (propylene ether) glycol sold under the trade name Pluracol P 2010 by Wyandotte Chemical Co. was degassed at room temperature for -1 hour and then charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. 111.4 g. (0.64 mole) of a 80-20% isomer mixture of tolylene-2,4-diisocyanate and tolylene- 2,6-diisocyanate respectively sold under the trade name Mondur TD 80 was added to the kettle. After 45 minutes, the temperature was raised to 120 C. and the reaction was continued for'50 minutes. A sample was removed and titrated for NCO resulting in 33.54 mg. NCO/g. 62.7 g. of diallyl amine was added at 105 C. and the reaction was continued for minutes. A sample was titrated resulting in an NCO content of 1.20 milligrams NCO/g. A vacuum was applied to the kettle for 1 hour at 90 C. followed by cooling under nitrogen. The resulting product had a molecular weight of about 2540-2580 and an ene functionality of 4.

10 g. of the thus formed polymer was charged to a 2 oz. glass jar along with 2 g. of pentaerythritol tetrakis (B- mercaptopropionate and 0.5 g. acetophenone. The liquid reactants were briefly stirred together and placed outdoors under ambient conditions. Within minutes a solid, odorless, elastomeric cured polythioether product was obtained.

30 Example 69 215 g. of poly(ethylene imine) commercially available from Dow Chemical Co. under the trade name Montrek 18 along with 41.5 g. allyl isocyanate was charged to a resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. The reactants were maintained at 70 to C. during addition. The reaction was continued for 1 hour at 70 C.

10 g. of the thus formed polymer were charged to a 2 02. glass jar along with'1.5 g. of pentaerythritol tetrakis (fl-mercaptopropionate) and 0.5 g. of acetophenone. The mixture was briefly stirred and placed outdoors in tthe sun light at ambient conditions. Within 2 hours a solid, selfsupporting, odorless, cured polymer product was formed.

The example was repeated using 180 g. of poly( ethylene imine) and 29.1 g. of allyl isocyanate under the same conditions and procedure. 10 g. of this polyene product was reacted with 2.1 g. of pentaerythritol tetrakis (fl-mercaptopropionate) and 5 g. of acetophenone. The mixture was briefly stirred and placed outdoors in the sun light at ambient conditions. Within 2 hours a solid, self-supporting, odorless, cured polymer product was formed.

Example 70 The polymeric polythiol (0.003' mole, i=2) from Example 65 was admixed with a stoichiometric amount (0.002 mole, i=3) of a monomeric polyene, glycerol trioleate (triolein, molecular weight 885) and 0.5 g. acetophenone. The jar containing the reactants after mixing was placed in the sunlight under ambient conditions. Within /2 hour the liquid mixture was converted to a self-supporting, solid, odorless, clear rubbery cured polythioether product.

The following example shows the operability of the instant invention when the polyene contains acetylenic linkages.

Example 71 400 g. (0.20 mole) of a commercially available liquid polymeric diisocyanate sold under the trade name Adiprene L- by E. I. du Pont de Nemours & Co. was charged to a dry resin kettle maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer and gas inlet and outlet. 25.2 g. (0.45 mole) of propargyl alcohol was charged to the kettle and the reaction was continued for 17 hours with stirring at 100 C. Thereafter the nitrogen atmosphere was removed and the kettle was evacuated 15 hours at 10 g. of the propargyl terminated liquid prepolymer, 3.0 g. of pentaerythritol tetrakis (B-mercaptopropionate) and 0.5 g. acetophenone were admixed together in a 2 oz. glass jar, stirred briefly and placed outdoors under ambient conditions. Within 2%. hours a solid, odorless, selfsupporting, cured elastomeric polymer product resulted.

Example 72 40 g. of Prepolymer I and 10 g. of a filler sold commercially under the trade name Hi Sil 233 by Columbia Southern Chemical Corp. were charged under nitrogen to a 200 ml. round bottom 3 necked flask maintained under a nitrogen atmosphere and mixed thoroughly. The flask was heated by a water bath to 60 C. under full vacuum for 2 hours. The flask was then allowed to cool under vacuum. 4 g. of pentaerythritol tetrakis (13- mercaptopropionate) was charged to the flask under nitrogen and the reaction was stirred continuously. The reaction was then exposed to ultraviolet light from the atmosphere outdoors and a solid, cured, odorless elastomeric product resulted within 15 minutes.

Example 73 125 g. of Prepolymer E from Example herein was charged to a Erlenmeyer flask equipped with a magnetic stirrer andconnected by tubing to another Erlenmeyer flask containing 54. g. of trimethylolpropane .tris(/3-..

stirring to insure good mixing, heat was removed and v the reaction was continued under nitrogen for 4 days.

No curing was observed. A sample of the unreacted material was removed from the Erlenmeyer flask under nitrogen and placed in a 2 oz. jar. The sample was exposed to ambient conditions outdoors and in about 2 minutes evidence of curing (viscosity change) was observed. With- 32 mole ene groups. In general the mole ratio significantly above or below I tend to give a high proportion of chain extension or grafting whereas mole ratios near 1 give predominantly chain extension and crosslinking. Occasionally, however, ratios necessary to give a solid as aforesaid may lie outside the stated range, and experimentation may be necessary to determine a suitable ratio to give a solid. This experimentation is easily carried out, and offers no difliculties to those skilled in the art.

The following Examples 75-80 show the ability to use mixtures of the polythiols and how to empirically determine the amount of polythiol necessary to form cured solid self supporting polymeric products by the instant invention.

As shown in Examples 75-80, g. of Prepolymer I from Example 8 were admixed with varying ratios of a mixture of polythiols and cured by ultraviolet light in the presence of acetophenone as a UV photoinitiator.

Polythiol mixture Aceto- Outdoor Curing Seli- Example Polyene Q-4Ei phenone curing time ShoreA support 0. polymer (g.) E23 (g.) (g.) site (mins.) hardness struct 75.. I 2. 0 0.5 X 7 Yes. I 2.3 0.6 0.5 X 7 25 Yes. I 1.7 1.2 0.5 X 9% 21 Yes. I 1.2 1.7 0.5 X 9% 7 Yes. I 0.6 2.3 0.5 X 52% 0 Yes. I 0 2.9 0.5 X N0.

1 P01 ene Pro 01 or I from Example 8. 2 Q4=pentaryl i r itol tetrakis (B mercaptopropionate) commercially available from Oarlisle Chemical Co.

8 E23=ethylene glycol bis (fl-mereaptopropionate).

No cure.

in 15. minutes, an odorless, solid elastomeric, cured polymer product was obtained, under UV light.

Example 74 10 g. of Prepolymer E from Example 5 was added to each of three 2 oz. jars. To one of the jars was added 3 ml. of benzene containing 0.5% based on the weight of the prepolymer of an antioxidant. sold under the trade name Santonox commercially available from Monsanto Chemical Co. To another of the jars containing Prepolymer E was-added 3 ml. of benzene containing 0.5% based on the weight of the prepolymer of an antioxidant sold under the trade name Dalpac FG commercially available from Hercules Powder Co. To the third jar was added 3 ml. of benzene as a control. To blend the components the jars were heated in a forced draft oven set at 150 C. for 25 minutes with frequent stirring. The jars were withdrawn from the oven and 1.3 g. of trimethylolpropane .tris (,S-mercaptopropionate) was added to each of the jars and curing was initiated indoors under ambient conditions- The control run, without any antioxidant present, cured within hour to a solid elastomeric polymer product. The example containing Dalpac FG cured to a solid polymer product after 12 days whereas the sample containing Santonox required more than 2 weeks before a solid self-supporting, cured polymeric product resulted.

The polyenes usedin the instant invention may be used as blends or mixtures of monoenes or polyenes having the same or different functionalities so long as the average functionality of the blend or mixture is at least 2. Similar- 1y, v.the polythiols used herein may be used as blends or mixtures ofmonothiols or polythiols having the same or diflerent functionalities as long as the average functionality of the blend or mixture is at least 2.

The polyene/polythiol mole ratio is selected so as to provide a solid final cured product, i.e., one that is nonflowing and structurally self-supporting under ambient conditions. In typical cases, as shown by the examples, this ratio can be about 0.2 to 5 moles thiol groups per The above formulations were briefly admixed for homogeneity and thereafter air cured indoors. Formulation I cured in approximately 6 hours to an elastomeric sealant whereas Formulation II cured in two days to an elastomeric sealant. Curing was accomplished more rapidly when the samples were placed outdoors in sunlight after mixing.

Example 82 10 g. of Prepolymer D were charged to a 2 oz. glass jar along with 0.7 g. of ethylene glycol bis (mercaptopropionate), 2.2 g. pentaerythritol tetrakis (mercaptopropionate), and 0.5 g. benzophenone. The reactants were briefly stirred and then placed between two pieces of glass plate each of 5 mil thickness. The glass plates were pressed together by hand to insure good adhesion, and then exposed to a Type RS Sunlamp at a surface radiation intensity of 4000 microwatts/am. for five minutes. An attempt was made to pull the glass plates apart. The glass broke before the adhesive was destroyed.

Example 83 50 g. of Prepolymer H along with 5.0 g. of pentaerythritol tetrakis (mercaptopropionate), and 0.5 g. of benzophenone were stirred together briefly in a glass jar and then poured into an aluminum mold in the shapeof a shallow dish. The mold was photocured by the procedure 33 of Example 82 after which the mold was torn away from the molded article which set to a solid in the exact shape of the mold.

Example 84 0.005 mole of Prepolymer E from Example was charged to a 2 oz. glass jar along with 0.0033 mole of trimethylolpropane tris (B-mercaptopropionate) and 0.5 g. of acetophenone. The reactants were stirred briefly and then coated on to a piece of 17 pt. clay coated paper by means of a No. rod. The paper was then placed outdoors in the sun light. After 10 mins. a clear solid coating resulted on the paper. The same technique was used successfully to coat cellophane, aluminum foil, steel plate stock, Mylar polyester film, plywood, and a concrete block of the type used in building construction.

Example 85 20 g. of the polymeric product from Example 9 was mixed with 2.2 g. of pentaerythritol tetrakis (fi-mercaptopropionate) commercially available from Carlisle Chemical Co. under the trade name Q43 and 0.5 g. of acetophenone in a 2 02. aluminum tray, stirred briefly and cured by irradiating with ultraviolet light from a Sylvania sun lamp. Within 4 minutes a solid, odorless, elastomeric product resulted.

Example 86 20 g. of the polymeric product from Example 10 was mixed in an aluminum dish with 2.2 g. of pentaerythritol tetrakis (,B-mercaptopropionate) commercially available from Carlisle Chemical Co. under the trade name Q43 and 0.5 g. of acetophenone. The mixture was irradiated for 3 minutes by ultraviolet light from a Sylvania sun lamp. The sample cured to a tack-free solid which had a color of less than 1 on the Gardner Scale. After exposure in a F adeometer for 47.2 hours, the color increased to a value of 4 on the Gardner Scale.

A similar polymer prepared from PPG-2025, tolylene-2,4-diisocyanate and allyl alcohol, cured with pentaerythritol tetrakis (B-mercaptopropionate) and acetophenone by irradiation with ultraviolet light also had a Gardner color of less than 1. However, after 47.2 hours in the Fadeometer the Gardner color rose to 13.

Example 87 10.25 g. of the polymeric product from Example 13 and 6.35 g. of pentaerythritol tetrakis (p-mercaptopropionate) were admixed along with 0.4 g. acetophenone in a beaker. A film approximately .035 inch thick (4.5 inch square) was spread on a glass plate and cured by irradiating it for 5 minutes with ultraviolet light from a Westinghouse sun lamp 8 to 10 inches above the film. The resultant cured product had a tensile strength of 368 p.s.i. and an elongation at failure of 27%. Its Shore A hardness was 80 to 85.

Example 88 10 g. of the polymer product from Example 18 was melted and 10 g. of solvent (equal volumes of toluene and 2-ethoxyethyl acetate) was added to lower the viscosity of the melt. To this solution was added 0.35 g. of pentaerythritol tetrakis (fi-mercaptopropionate). The solution was mixed and a 0.035 inch sheet was cast and irradiated for 30 minutes with a Westinghouse sun lamp. The resultant, clear, cured product crystallized slowly to a white opaque material which had a tensile strength of 6310 p.s.i. and an elongation at failure of 720%. It had a Shore A hardness of over 100.

Example 89 6 g. of glycerol trioleate (Armour Industrial Chemical Co.) and 2.4 g. of pentaerythritol tetrakis (pt-mercaptopropionate) were dissolved in an ethanolbenzene solution and placed in an aluminum tray. 1.0 g. of acetophenone was added and admixed and the mixture was exposed to the ultraviolet rays of the sun for 3 days. A cured solid film was formed in 3 days.

Example 90 10.6 g. of decaglycerol dioleate (Drew Chemical Corp.) and 2.0 g. of pentaerythritol tetrakis (fi-mercaptopropionate) were dissolved in ethanol, 1.0 g. of acetophenone was admixed therewith and the mixture in an aluminum tray was placed outdoors in the sunlight. After 3 days a cured film was formed.

Example 91 5.6 g. of decaglyercol decaoleate (Drew Chemical Corp.) and 2.0 g. of pentaerythritol tetrakis (fl-mercaptopropionate) were admixed in an ethylene-benzene solution in an aluminum tray. 1.0 g. of acetophenone was added to the mixture and the mixture was placed in the sun light. After 3 days a cured film resulted.

Example 92 5.5 g. of decaglycerol decaoleate (Drew Chemical Corp.) and 2.0 g. of ethylene glycol bis (fi-mercaptopropropionate) commercially available from Carlisle Chemical Co. under the trade name E-23 were dissolved in an ethanol-benzene solution in an aluminum tray. 1.0 g. of acetophenone was added to the mixture and the mixture was placed in the sun. After 3 days a semi-solid cured film resulted.

Example 93 5.2 g. of decaglycerol dioleate (Drew Chemical Corp.) and 2.0 g. of ethylene glycol bis (B-mercaptopropionate) were dissolved in ethanol in an aluminum tray. 1.0 g. of acetophenone was added to the mixture and the mixture was placed in the sun. After 3 days the product had not solidified to a crosslinked network.

Example 94 94.5 g. of dimer acid commercially available from Emery Industries Inc. under the trade name Empol 1010 and 103.5 g. of allyl alcohol were admixed in benzene in a 2 neck flask. The reaction was heated gently for 19 hours at C. at which time it was determined by titration that less than 6% of the carboxyl group content was unreacted. The reaction was discontinued and the reactants were Washed with Water. The thus formed emulsion was salted out thoroughly, the benzene layer was separated and dried to remove residual moisture. The benzene was distilled oif in vacuum to obtain the diallyl ester of dimer acid.

The diallyl ester of the dimer acid product was admixed with Q-43 in a 1:1 mole ratio and 1.0 g. acetophenone in an aluminum tray and cured in the sun. After 2 hours a cured solid product resulted.

The curing example was repeated except that the mole ratio of the diallyl ester of dimer acid to Q-43 was 2:1. The cured product was harder than the product obtained under the 1:1 mole ratio of diallyl ester to Q-43.

14 g. of dimer acid, 6 g. of pentaerythritol tetrakis (B-mercaptopropionate) and 1.0 g. of acetophenone were mixed in an aluminum tray. The mixture was placed in the sun. After 22 hours the product had not solidified to a crosslinked network.

EXAMPLES 95-117 UV thrucure rate, Shore A Sample Photocuring 1 rate mils/ hardness Number Polyene Source of Polyene accelerator Polythiol 2 minute UV cured 1,2,4-triviny1cyc1ohexane- Aldrich Chem. 00., Inc Beuzophenone Q-43 23. 3 70 1,5-h nx'nrlipnn (in Q-43 35 6O Dlallyl terephthalate. Chemicals Procurement Lab. Inc do (.1-43 21. 0 60 Diallyl oxalate d 6. 0 80 Diallyl1, t-cyclohexane-dicarboxylate 0 do Q-43 3.0 70 Tetraallyl orthosilicate Aldrich Chem. 00., Inc do Q-43 8. 8 60 Diallyl diphenylsilane Chemicals Procurement Lab., Inc do Q-43 43. 7 75 Diallyl allyl phosphonate. Aldrich Chem. 00., Inc do Q43 17. 90 Diallyl phenyl phosphite K. & K. Laboratories, Intdn Q-43 11, 7 70 N,N-diallylformamide Aldrich Chem. 00 m; rlo Q-43 7. 0 59 105 Ng,N, ,-tetraally -methylenadia- Monomer-Polymer Labs Inc do Q-43 4. 4 75 no. 106 Triallyl cyanurate Aldrich Chemical CO Dibenzosuberone P-83 7.0 35 4-vinyl-1-eyclohexene K. & K. Laboratories, Inc Benmnhenone 1. 6 70 Diethyleneglycol divinyl other (.9 Polysciences, Inc

mole). D1benzosuberone. 36. 6 42 Diallyl amine (.1 mole) Monomer-Polymer Labs, Inc Triallyl phosphate Aldrich Chemical 00., Inc do P-33 10.0 20 110 Diallyl carbonate Chemical Proc. Labs, Im1 do Q-43 125. 0 63 111 N-diallyl plperazine. do -do Q-43 25.0 57 112 lyl diglycol carbonate CR-39 from PP G Ind. Inc do Q43 100.0 62 113 Polymeric diene Example 9 Tri(o-to1yl) phosphine Q-43 5 2 114 do do C014 (15 parts/100) plus Q-43 5 phenanthrene. 1 l 5 do do o-llzletthoxyphenylmethyl Q,43 10 20 e one. 116 do do o-Methoxybenzaldehyde..- Q-43, 1 117 do do CCI parts/100) Q43 3 1 Concentration of photocuring rate accelerator varied from 0.2 to 1.5 parts/100 parts photocurable composition. Q-43 is pentaerythritol tetrakis (fl-mercaptopropwnate); P-33 1s tnmethylolpropane tris (fl-mercaptopropionate). The polythiol is used in the theoretical equivalent amount based on the polyene used.

3 Sample thickness ranged from 35 to 140 mils; UV source was a 275 watt Type RS sun lamp; incident radiation intensity at surface of photocurable composition was 4,000 microwatts/cms.

Example 1 18 916 g. (0.46 mole) of a commercially available liquid polymeric diisocyanatc sold under the trade name Adiprene L-100 by E. I. du Pont de Nemours and Co. was charged to a dry flask maintained under a nitrogen atmosphere and equipped with a condenser, stirrer, thermometer andgas inlet and outlet. 197 g. (0.92 mole) of the diallyl ether of trirnethylolpropane was charged to the vessel along with 0.56 g. dibutyltin dilaurate catalyst. The flask and contents were heated with stirring for minutes at 50 C. to yield a polytetracne of about 2400 M.W.

To the tetraene was added 230 g. pentaerythritol tetrakis, (5-mercaptopropionate), 18.4 g. benzophenone, 1.2 g. dilaurylthio-dipropionate, 136 grams of dioctyl phthalate, and 1.2 g. Plastanox 2246 (hindered phenol antioxidant sold by American Cyanamid Co.). This photocurable liquid composition was cast on a glass plate in a layer 40 mls thick. It was then exposed to UV radiation from a 275 Watt Type RS sun lamp. The intensity of the radiation incident on the surface of the layer was seconds and cured to a solid through the entire thickness in less than 20 seconds, or at a liquid-to-solid conversion rate of over 120 mils/minute. The solid rubbery product had a Shore A hardness of 72, a tensile strength of 150 p.s.i. and an elongation at failure of 40 percent.

The solid cured polythioether polymer products resulting from the instant invention have many and varied uses. Examples of some uses include but are not limited to adhesives; caulks; clastomeric sealants; coatings, encapsulating or potting compounds; liquid castable elastomers; thermosct resins; impregnants for fabric, cloth, fibrous webs" and other porous substrates; laminating adhesives and coatings; mastics; glazing compounds; fiberglass reinforced composites; sizing or surface finishing agents, filleting compounds; cure in place gasketing compounds; rocket fuel binders; foamable thermosetting resins or elastomers; molded articles such as gaskets, diaphragms, balloons, automobile tires, etc.

The molecular weight of the polyenes of the present invention may be measured by various conventional methods, including solution viscosity, osmotic pressure and gel permeation chromatography. Additionally, the molecular weight may be calculated from the known molecular weight of the reactants.

The viscosity of the polyenes and polythiols may be measured on a Brookfield Viscometer at 30 or 70 C. in accord with the instructions therefor.

The components to be cured may be prepared as either single-packaged or multi-packaged liquid polymer systems which may be cured to solid polythioether elastomers without liberating gaseous by-products which cause bubbles and voids in the vulcanizate. Thus, there is provided curable liquid polymer systems composed of polyenes and polythiols in which the components individually are storage stable and which are not sensitive to or deteriorated by traces of moisture or oxygen containing gas such as may be encountered during normal storage or handling procedures. Solid resinous. or elastomeric products may be prepared fromflowable liquids in a system in which the rate of curing may be inhibited or retarded by the use of chemical inhibitors, antioxidants, inert atmospheres and the like. The cured product may be characterized as in the thermally and oxidatively stable state since there is no reactive carbon-to-carbon unsaturation in the main backbone chain.

As used herein the term polyene and the term polyne refers to single or complex species of alkenes or alkyncs having a multiplicity of terminal reactive carbon-to-carbon unsaturated-functional groups per average molecule. For example, a diene is a polyene that has two reactive carbon-to-carbon double bonds per average molecule, while a diyne is a polyyne that contains in its structure two reactive carbon-to-carbon triple bonds per average molecule. Combinations of reactive double bonds and reactive triple bonds within the same molecule are also possible such as for monovinylacetylene which is a polyeneyne under this definition. For purposes of brevity all these classes of compounds are referred to hereafter as polyenes.

In defining the position of the reactive functional carbon-to-carbon unsaturatio'n, the term terminal is intended to mean that functional unsaturation is at an end of the main chain in the molecule; whereas by near terminal is intended to mean that the functional unsaturation is not more than 10 carbon atoms and typically less than 8 carbon atoms from an end of the main chain in the molecule. The term pendant means that the reactive carbon-to-carbon unsaturation is located terminal or near? terminal in a branch of the main chain as contrasted to a position at or near the ends of the main chain. For

purposes of brevity all of these positions are referred to herein generally as terminal unsaturation.

Functionality as used herein refers to the average number of ene or thiol groups, per molecule in the polyene or polythiol, respectively. For example a triene is a polyene with an average of three reactive carbon-to-carbon unsaturated groups per molecule and thus has a functionality (f) of three. A dithiol is a polythiol with an average of two thiol groups per molecule and thus has a functionality (f) of two.

It is to be understood that the functionality of the polyene and the polythiol component is commonly expressed in whole numbers although in practice the actual functionality may be fractional. For example, a polyene component having a nominal functionality of 2 (from theoretical considerations alone) may in fact have an effective functionality of somewhat less than 2. In an attempted synthesis of a diene from a glycol in which the reaction proceeds to 100% of the theoretical value for complete reaction, the functionality (assuming 100% pure starting materials) would be 2.0. If however, the reaction were carried to only 90% of theory for complete reaction, about of the molecules present would have only one ene functional group, and there may be a trace of material that would have no ene functional groups at all. Approximately 90% of the molecules, however, would have the desired diene structure and the product as a whole then would have an actual functionality of 1.9.

' Such a product is useful in the instant invention and is as contrasted to the term unreactive carbon-to-carbon unsaturation which means I I C=C groups found in aromatic nucleii (cyclic structures exemph'fied by benzene, pyridine, anthracene, and the like) which do not under the same conditions react with thiols to give thioether linkages.

Highly water-sensitive groups are intended to include, for example, isocyanate, acylhalide such as acylchloride, anhydride and the like which readily react with water, alcohols, ammonia, amines and the like.

Odorless has been used herein to mean the substantial absence of the well-known olfensive and sometimes obnoxious odors that are characteristic of hydrogen sulfide and the derivative family of compounds known as mercaptans.

The term non-yellowing means the substantial resistance during prolonged exposure to actinic radiation such as exposure in sunlight, to unsightly or uncontrollable discoloration.

It is understood that the foregoing detailed description is given merely by way of illustration and that many variations may be made therein without departing from the spirit of this invention.

What is claimed is:

1. A photocurable composition useful for obtaining an essentially odorless, solid polythioether, said photocurable composition consisting essentially of (A) a thermally unsaturated polyene component which comprises the formula:

wherein m is an integer of at least 2; wherein X is nail.

38 where R is a radical selected from the group consisting of hydrogen, fluorine, chlorine, butyl, thienyl, pyridyl, phenyl and substituted phenyl, benzyl and substituted benzyl, alkyl and substituted alkyl, alkoxy and substituted alkoxy, cycloalkyl and substituted cycloalkyl; said substituents on said substituted members selected from the group consisting of nitro, chloro, fluoro, acetoxy, acetamide, phenyl, benzyl, alkyl, alkoxy and cycloalkyl; said alkyl and alkoxy having from 1 to 9 carbon atoms and said cycloalkyl having from 3 to 8 carbon atoms; wherein [A] is free of reactive carbon-to-carbon unsaturation; free of highly water-sensitive members; and is a polyvalent chemically compatible member of the group consisting of carbonate, carboxylate, carbonyl, ether, silane, silicate, phospho nate, phosphite, phosphate, alkyl and substituted alkyl, cycloalkyl and substituted cycloalkyl, aryl and substituted aryl, urethane and substituted urethane, urea and substituted urea, amine and substituted amine, amide and substituted amide, hydroxyl, heterocyclic carbon containing radical, and mixtures thereof; said substituents on said members substituted being defined above, said component having a molecular weight in the range from about 64 to 20,000; and a viscosity in the range from essentially 0 to 20 million centipoises at C.; and (B) a polythiol component having a molecular weight in the range from about 50 to about 20,000 of the general formula:

formula:

cH,-f: om-E m wherein a and b are integers greater than 1;

R is a member of the group consisting of hydrogen and alkyl;

R is a member of the group consisting of hydrogen,

and saturated alkyl;

R, is a divalent derivative of the group consisting of phenyl, benzyl, alkyl, cycloalkyl, substituted phenyl, substituted benzyl, substituted alkyl and substituted cycloalkyl,

said alkyl, cycloalkyl and substituents on members substituted being defined as in claim 1.

3. The composition of claim 1 wherein the photocuring rate accelerator is a member selected from the group consisting of aryl aldehyde, diaryl ketone, alkyl aryl ketone, triaryl phosphine, and a blend of carbon tetrahalide with polynuclear aromatic hydrocarbon.

4. The composition of claim 1 wherein the mole ratio of ene to thiol is from about 0.5/1 to about 2/ 1.

5. The composition of claim 1 wherein the mole ratio of ene to thiol is from about 0.75/1 to about 1.5/1.

6. A process of forming essentially odorless solid polythioether which comprises 39 40 (I) Admixing: (B) a polythiol component having a molecular (A) a terminally unsaturated polyene component weight in the range from about 50 to about which comprises the formula: 20,000 of the general formula:

'I f f l m T wherein m is an integer of at least 2; wherein WhereinRa is a p l' Organic moiety free X is from reactive carbon-to-carbon unsaturation R R and n is at least 2, the sum of m and n being a greater than 4, with the ene/thiol mole ratio 1 being selected so as to provide a cross-linked R solid, self-supporting cured product; and

(c) a photocuring rate accelerator, and thereafter (II) Exposing the mixture to actinic light. R a radical selected from the group 7. The solid product prepared by the process of claim sisting of hydrogen, fluorine, chlorine, furyl, thienyl, pyridyl, vphenyl and substituted 8. The process of clalm 6 wherein the actmrc light is where phenyl, benzyl and substituted benzyl, alkyl ultraviolet radiation having a wavelength between aboutand" substituted alkyl, alkoxy and substi- 2000 A and ab0l1t4000 tuted lk cycloalkyl andsubstituted 9. The process of claim 6 whereln the composition cloalkyl; said substituents o id b icontains from 0.0005 to 50 parts by weight of a phototuted members selected from the group curing fate acceleratorconsisting of nitro, chloro, fluoro, acetoxy, 10. The process of claim 6 wherein the photocuring acetamide, phenyl, benzyl, alkyl, alkoxy and rate accelerator is selected from the group consisting of cycloalkyl; said alkyl and alkoxy having aryl aldehyde; diaryl ketone; alkyl aryl ketone; triaryl from 1 to 9 carbon atoms and said cyclophosphine; a blend of carbon tetrahalide with polynuclear alkyl having from 3 to 8 carbon atoms; aromatic hydrocarbon. wherein 11. An article comprising the composition of claim 6 [A] is free of reactive carbon-to-carbon unas a coating on a substrate.

saturation; free of highly water-sensitive 12. An article comprising the composition of claim 6 members; and is a polyvalent chemically as an adhesive between two substrates. compatible member of the group consisting 13. An article comprising the composition of claim 6 of carbonate, carboxylate, carbonyl, ether, as an elastomeric sealant. silane, silicate, phosphonate, phosphite, 14. A shaped, molded article cast from the composition phosphate, alkyl and substituted alkyl, cyof claim6. cloalkyl and substituted cycloalkyl, aryl 15. The composition of claim 1 wherein the polyene and substituted aryl, urethane and subhas the formula:

CH3 CH1 CH1 0 0 0 o 1 0H, CH,=CHI'\i-o11ioH,-o-i J-NH -H NH-iio (CzH40);- C:Ht0 (ClHBO) NH NHii0-cHt0H,-r I

y I (IJH n I stituted urethane, urea and substituted urea, where the sum of x+y+z is at least 1, and n is an integer amine and substituted amine, amide and of O or greater. substituted amide, hydroxyl, heterocyclic 16. The composition of claim 1 wherein the polyene carbon containing radical, and mixtures has the formula:

thereof; said substituents on said members where n is an integer of O or greater. substituted being defined above, said com- 17. The composition of claim 1 wherein the polyene ponent" having a molecular weight in the has the formula:

o o I f f I CH =0H-NH-d-OC H 0 0 H 0 C411 0 J--NHCH=OH range from about 64 to 20,000; and a viswhere the sum of x+y'+z is at least 1.

cosity in the range from essentially 0 to 20 million centipoises at C.; and (References on following page) 

